A Phase 2a Randomized, Double-Blind, Dose-Optimizing Study to Evaluate the Immunogenicity and Safety of a Bivalent DNA Vaccine for Hemorrhagic Fever with Renal Syndrome Delivered by Intramuscular Electroporation.

Hantaan virus (HTNV) and Puumala virus (PUUV) are pathogenic hantaviruses found in Asia and Europe, respectively. DNA vaccines targeting the envelope glycoproteins of these viruses have been constructed and found to elicit neutralizing antibodies when delivered to humans by various technologies including intramuscular electroporation. Here, we report findings from a Phase 2a clinical trial of a combined HTNV/PUUV DNA vaccine delivered at varying doses and administration schedules using the Ichor Medical Systems TriGrid intramuscular electroporation delivery technology. The study was designed to characterize the effects of DNA vaccine dose and number of administrations on the frequency and magnitude of immunological response. Subjects (n = 120) were divided into four cohorts. Cohorts 1 and 2 received a dose of 2 mg of DNA (1 mg per plasmid), and cohorts 3 and 4 received a dose of 1 mg of DNA (0.5 mg per plasmid) each vaccination. Each of the four cohorts received a series of four administrations (days 0, 28, 56 and 168). For cohorts 1 and 3, the DNA vaccine candidate was delivered at each of the four administrations. For cohorts 2 and 4, in order to maintain blinding, subjects received the DNA vaccine on days 0, 56 and 168, but on day 28 received only the phosphate buffered saline vehicle rather the DNA vaccine. Sera were collected on days 0, 28, 56, 84, 140, 168, 196, 252 and 365 and evaluated for the presence of neutralizing antibodies by PUUV and HTNV pseudovirion neutralization assays (PsVNAs). Day 84 was also evaluated by a plaque reduction neutralization test (PRNT). Overall the PsVNA50 geometric mean titers (GMTs) and seropositivity rates among cohorts were similar. Cohort 3 exhibited the highest frequency of subjects that became seropositive to both PUUV and HTNV after vaccination, the highest peak GMT against both viruses, and the highest median titers against both viruses.

Combined skin and muscle vaccination differentially impact the quality of effector T cell functions: the CUTHIVAC-001 randomized trial.

Targeting of different tissues via transcutaneous (TC), intradermal (ID) and intramuscular (IM) injection has the potential to tailor the immune response to DNA vaccination. In this Phase I randomised controlled clinical trial in HIV-1 negative volunteers we investigate whether the site and mode of DNA vaccination influences the quality of the cellular immune responses. We adopted a strategy of concurrent immunization combining IM injection with either ID or TC administration. As a third arm we assessed the response to IM injection administered with electroporation (EP). The DNA plasmid encoded a MultiHIV B clade fusion protein designed to induce cellular immunity. The vaccine and regimens were well tolerated. We observed differential shaping of vaccine induced virus-specific CD4 + and CD8 + cell-mediated immune responses. DNA given by IM + EP promoted strong IFN-γ responses and potent viral inhibition. ID + IM without EP resulted in a similar pattern of response but of lower magnitude. By contrast TC + IM (without EP) shifted responses towards a more Th-17 dominated phenotype, associated with mucosal and epidermal protection. Whilst preliminary, these results offer new perspectives for differential shaping of desired cellular immunity required to fight the wide range of complex and diverse infectious diseases and cancers.

A Phase 1 clinical trial of Hantaan virus and Puumala virus M-segment DNA vaccines for haemorrhagic fever with renal syndrome delivered by intramuscular electroporation.

Haemorrhagic fever with renal syndrome (HFRS) is endemic in Asia, Europe and Scandinavia, and is caused by infection with the hantaviruses Hantaan (HTNV), Seoul (SEOV), Puumala (PUUV), or Dobrava (DOBV) viruses. We developed candidate DNA vaccines for HFRS expressing the Gn and Gc genes of HTNV or PUUV and evaluated them in an open-label, single-centre Phase 1 study. Three groups of nine participants each were vaccinated on days 0, 28 and 56 with the DNA vaccines for HTNV, PUUV, or a mixture of both vaccines using the Ichor Medical Systems TriGrid Intramuscular Delivery System. All vaccinations consisted of a total dose of 2.0 mg DNA in an injected volume of 1 mL saline. For the combined vaccine, the mixture contained equal amounts (1.0 mg) of each DNA vaccine. There were no study-related serious adverse events. Neutralizing antibody responses were measured by a plaque reduction neutralization test. Neutralizing antibody responses were detected in five of nine and seven of nine individuals who completed all three vaccinations with the HTNV or PUUV DNA vaccines, respectively. In the combined vaccine group, seven of the nine volunteers receiving all three vaccinations developed neutralizing antibodies to PUUV. The three strongest responders to the PUUV vaccine also had strong neutralizing antibody responses to HTNV. These results demonstrate that the HTNV and PUUV DNA vaccines delivered by electroporation separately or as a mixture are safe. In addition, both vaccines were immunogenic, although when mixed together, more participants responded to the PUUV than to the HTNV DNA vaccine.

A DNA vaccination regime including protein boost and electroporation protects cattle against foot-and-mouth disease.

Protection against foot-and-mouth disease (FMD) using DNA technology has been documented for sheep and pigs but not for the highly susceptible species of cattle. Twenty-five Holstein Friesian cross-bred cattle were vaccinated twice, 21 days apart, with a DNA vaccine containing the capsid coding region (P1) along with the non-structural proteins 2A, 3C and 3D (pcDNA3.1/P1-2A3C3D) of O(1) Kaufbeuren alone or coated onto PLG (d,l-lactide-co-glycolide) microparticles. In some pcDNA3.1/P1-2A3C3D was also combined with an adjuvant plasmid expressing bovine granulocyte macrophage colony stimulating factor (GM-CSF). DNA vaccinations were administered intramuscularly with, or without, the use of electroporation and at 42 days post primary vaccination cattle received a protein boost of 146S FMD virus (FMDV) antigen and non-structural protein 3D. For comparison, four cattle were vaccinated with a conventional FMD vaccine and two more included as unvaccinated controls. Apart from those immunised with PLG microparticles all cattle were challenged with 10(5) TCID(50) cattle adapted O(1) Lausanne FMDV virus at day 93 post primary vaccination. All DNA vaccinated cattle regardless of regime developed good humoral and cell mediated responses prior to challenge. The best overall virus neutralising antibody, IFN-γ and clinical protection (75%) were seen in the cattle whereby the DNA was delivered by electroporation. In contrast, only 25% of cattle vaccinated with the DNA vaccine without electroporation were clinically protected. The addition of GM-CSF in combination with electroporation further improved the efficacy of the vaccine, as demonstrated from the reduction of clinical disease and virus excretions in nasal swabs. We thus demonstrate for the first time that cattle can be clinically protected against FMDV challenge following a DNA prime-protein boost strategy, and particularly when DNA vaccine is combined with GM-CSF and delivered by electroporation.

Electroporation for DNA immunization: clinical application.

DNA immunization is an attractive technology owing to its potential to induce balanced and long-lived immune responses. However, progress into the clinic has been hampered by the relatively low magnitude of the immune response typically induced following administration in large target species, which is likely due to low transfection efficiency as well as insufficient recruitment of antigen-presenting cells to the injection site. Electroporation addresses both of these limitations by inducing transiently enhanced cell membrane permeability, thus facilitating uptake of the DNA into the host cell and creating a low level of inflammation conducive to enhanced influx of antigen-presenting cells to the injection site. Consequently, electroporation-mediated delivery of DNA vaccines results in very significant improvements in the transfection efficiency and immune responses in comparison to conventional injection. Importantly, electroporation is effective in virtually every animal model tested to date and has a favorable safety profile, which is promising for clinical application. In support of the potential for electroporation in human disease situations, early clinical results suggest that the immunogenicity of DNA vaccines is greatly improved when delivered with electroporation.

Codon-optimization of the hemagglutinin gene from the novel swine origin H1N1 influenza virus has differential effects on CD4(+) T-cell responses and immune effector mechanisms following DNA electroporation in mice.

DNA electroporation is a powerful vaccine strategy that could be rapidly adapted to address emerging viruses. We therefore compared cellular and humoral immune responses in mice vaccinated with DNA expression plasmids encoding either the wildtype or a codon-optimized sequence of hemagglutinin from the novel swine origin H1N1 influenza virus. While expression of HA from the wildtype sequence was hardly detectable, the H1N1 hemagglutinin was well expressed from the codon-optimized sequence. Despite poor expression of the wildtype sequence, both plasmids induced similar levels of CD4(+) T-cell responses. However, CD8(+) T-cell and antibody responses were substantially higher after immunization with the codon-optimized DNA vaccine. Thus, efficient induction of immune effector mechanisms against HA of the novel H1N1 influenza virus requires codon-optimization of the DNA vaccines. Since DNA vaccines and several viral vector vaccines employ the same cellular RNA-Polymerase II dependent expression pathway, the poor expression levels from wildtype HA sequences might also limit the induction of immune effector mechanisms by such viral vector vaccines.

Potentiation of an anthrax DNA vaccine with electroporation.

DNA vaccines are a promising method of immunization against biothreats and emerging infections because they are relatively easy to design, manufacture, store and distribute. However, immunization with DNA vaccines using conventional delivery methods often fails to induce consistent, robust immune responses, especially in species larger than the mouse. Intramuscular (i.m.) delivery of a plasmid encoding anthrax toxin protective antigen (PA) using electroporation (EP), a potent DNA delivery method, rapidly induced anti-PA IgG and toxin neutralizing antibodies within 2 weeks following a single immunization in multiple experimental species. The delivery procedure is particularly dose efficient and thus favorable for achieving target levels of response following vaccine administration in humans. These results suggest that EP may be a valuable platform technology for the delivery of DNA vaccines against anthrax and other biothreat agents.

Electroporation-based DNA transfer enhances gene expression and immune responses to DNA vaccines in cattle.

Despite the potential of DNA vaccines to induce strong, balanced immune responses in small experimental species, the immune responses to DNA immunization in larger species have generally been moderate and inconsistent. In this study, the TriGridtrade mark Delivery System (TDS), an electroporation-based DNA delivery platform, was evaluated for administration of DNA vaccines to calves. When compared to conventional intramuscular delivery, TDS-based delivery markedly and consistently enhanced gene expression from a plasmid encoding a reporter gene, secreted alkaline phosphatase, and improved cell-mediated and humoral immune responses to a plasmid encoding a model antigen, hepatitis B surface antigen. Importantly, the TDS-based procedure was well tolerated by the calves, which did not need to be anesthetized or sedated. These results suggest that the TDS is a useful delivery method for DNA vaccines in cattle.

Enhancement of immune responses to an HBV DNA vaccine by electroporation.

These studies document the ability of electroporation (EP)-based DNA vaccination to induce multi-specific CTL responses to hepatitis B virus (HBV) DNA vaccination in normal mice and marked immune responses to multivalent HBV DNA immunization in larger animal species. These results suggest that electroporation-mediated HBV DNA vaccination is worth pursuing as a treatment for chronic HBV infection.